CN104321369A - Variable TG article, method of making, and use of same - Google Patents
Variable TG article, method of making, and use of same Download PDFInfo
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- CN104321369A CN104321369A CN201380026536.4A CN201380026536A CN104321369A CN 104321369 A CN104321369 A CN 104321369A CN 201380026536 A CN201380026536 A CN 201380026536A CN 104321369 A CN104321369 A CN 104321369A
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Links
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- 239000001273 butane Substances 0.000 description 1
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Classifications
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16J—PISTONS; CYLINDERS; SEALINGS
- F16J15/00—Sealings
- F16J15/16—Sealings between relatively-moving surfaces
- F16J15/18—Sealings between relatively-moving surfaces with stuffing-boxes for elastic or plastic packings
- F16J15/20—Packing materials therefor
-
- C—CHEMISTRY; METALLURGY
- C08—ORGANIC MACROMOLECULAR COMPOUNDS; THEIR PREPARATION OR CHEMICAL WORKING-UP; COMPOSITIONS BASED THEREON
- C08L—COMPOSITIONS OF MACROMOLECULAR COMPOUNDS
- C08L81/00—Compositions of macromolecular compounds obtained by reactions forming in the main chain of the macromolecule a linkage containing sulfur with or without nitrogen, oxygen or carbon only; Compositions of polysulfones; Compositions of derivatives of such polymers
-
- C—CHEMISTRY; METALLURGY
- C09—DYES; PAINTS; POLISHES; NATURAL RESINS; ADHESIVES; COMPOSITIONS NOT OTHERWISE PROVIDED FOR; APPLICATIONS OF MATERIALS NOT OTHERWISE PROVIDED FOR
- C09K—MATERIALS FOR MISCELLANEOUS APPLICATIONS, NOT PROVIDED FOR ELSEWHERE
- C09K3/00—Materials not provided for elsewhere
- C09K3/10—Materials in mouldable or extrudable form for sealing or packing joints or covers
-
- E—FIXED CONSTRUCTIONS
- E21—EARTH OR ROCK DRILLING; MINING
- E21B—EARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B33/00—Sealing or packing boreholes or wells
- E21B33/02—Surface sealing or packing
- E21B33/03—Well heads; Setting-up thereof
- E21B33/06—Blow-out preventers, i.e. apparatus closing around a drill pipe, e.g. annular blow-out preventers
-
- E—FIXED CONSTRUCTIONS
- E21—EARTH OR ROCK DRILLING; MINING
- E21B—EARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B33/00—Sealing or packing boreholes or wells
- E21B33/10—Sealing or packing boreholes or wells in the borehole
- E21B33/12—Packers; Plugs
- E21B33/1208—Packers; Plugs characterised by the construction of the sealing or packing means
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16J—PISTONS; CYLINDERS; SEALINGS
- F16J15/00—Sealings
- F16J15/02—Sealings between relatively-stationary surfaces
- F16J15/021—Sealings between relatively-stationary surfaces with elastic packing
- F16J15/022—Sealings between relatively-stationary surfaces with elastic packing characterised by structure or material
-
- C—CHEMISTRY; METALLURGY
- C09—DYES; PAINTS; POLISHES; NATURAL RESINS; ADHESIVES; COMPOSITIONS NOT OTHERWISE PROVIDED FOR; APPLICATIONS OF MATERIALS NOT OTHERWISE PROVIDED FOR
- C09K—MATERIALS FOR MISCELLANEOUS APPLICATIONS, NOT PROVIDED FOR ELSEWHERE
- C09K3/00—Materials not provided for elsewhere
- C09K3/10—Materials in mouldable or extrudable form for sealing or packing joints or covers
- C09K2003/1034—Materials or components characterised by specific properties
- C09K2003/1068—Crosslinkable materials
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Abstract
An article includes a crosslinked product of: a first crosslinked polymer and a second crosslinked polymer, wherein the article has a gradient in glass transition temperature. A process for making the article includes combining a first crosslinked polymer and a second crosslinked polymer to form a composition; compressing the composition; heating the composition; and crosslinking the composition to form the article, the article having a gradient in glass transition temperature. An article can be a seal that includes a first portion including a crosslinked product of: a first crosslinked polymer and a second crosslinked polymer; and a second portion including a polymer which is different than a constituent polymer in the first portion, wherein the seal has a gradient in glass transition temperature.
Description
The related application of cross reference
This application claims the rights and interests of the U. S. application 13/478,387 that on May 23rd, 2012 submits to, it is incorporated herein by reference in this entirety.
Background of invention
Resilient material is used in different sealing applications.Such sealing member can be dynamic or static seal.Environmentally, elastomeric seal can experience the temperature of certain limit, pressure and chemical.Elastomeric seal can be used for high vacuum to many times of normal atmosphere with slightly lower than the temperature such as 150 DEG C of room temperature to rising.Inertia and reactant gas and liquid are all exposed to elastomerics.Although there is not desirable elastomeric seal, elastomerics shows for chemical attack, thermal destruction, leakage rate and the tolerance of certain limit extruded.In industrial gas oil, at given temperature, pressure and in work-ing life, while being exposed to eroding chemical, elastomerics should keep its mechanical property at " hygrometric state " under " dry state " condition.
Even if when using up-to-date technology, also still need such elastomerics or any other polymer materials, its under hygrometric state condition when high temperature function good, and maintain their mechanical property.High temperature polymer (it is chemicals-resistant under only drying conditions) is easy to obtain.Such polymkeric substance comprises some thermoplastic polyimide (TPI) and polybenzimidazole (PBI).The polymkeric substance that can be used for the chemicals-resistant under low temperature and hygrometric state condition is also easy to obtain.The example of these polymkeric substance comprises some polyethylene and polypropylene.Under the condition of high temperature and corrosive fluid, often use fluoropolymer, because they are considered to have best thermostability and chemical-resistant usually.The example of fluoropolymer comprises tetrafluoroethylene, and some other fluoroelastomers and Perfluoroelastomer.The fluoropolymer of some grade it is said the maximum continuous use temperature with 327 DEG C.But, even if best Perfluoroelastomer also can high temperature through time deliquescing, lose the ability of their under high pressure sealing off gap.Equally, fluoroelastomer or Perfluoroelastomer tend to when high temperature contacts with different downhole fluids form crackle.
Replace elastomerics although research widely concentrates on or increase them for high pressure, high temperature and tolerance that is chemical and the mechanically degraded of environment such as in conditions down-hole of harshness, but still need the chemical-resistant with improvement, particularly the elastomerics of chemical-resistant at this high temperature.If can obtain the chemical-resistant of improvement, and insignificantly producing adverse influence to other desired properties of elastomerics such as mechanical property such as elasticity, resistance to extrudability and overall construction intensity, then can be further advantage.Received is in the art such materials and methods, it is for elastomerics used in device such as pkr, explosion-proof component, O shape ring, packing ring etc., it maintains good mechanical property when contacting with corrosive fluid within the continuous print usage period at high temperature and high pressure.
Summary of the invention
In one embodiment, disclose a kind of goods, it comprises: following cross-linking products: the first cross-linked polymer; With the second cross-linked polymer, the second-order transition temperature of these goods has gradient.
In another embodiment, a kind of goods, it comprises: following cross-linking products: the first cross-linked polymer; With the second cross-linked polymer, wherein the second-order transition temperature of these goods has gradient, cross-linking density has gradient, and these goods are configured to have self-supporting (self backup) performance in the minimum Tg value of this second-order transition temperature gradient to the temperature being less than maximum Tg value.
In another embodiment, a kind of method manufacturing goods, it comprises: merge the first cross-linked polymer and the second cross-linked polymer to form composition; Compression said composition; Heating said composition; With crosslinked said composition to form this goods, the second-order transition temperature of these goods has gradient.
In yet another embodiment, a kind of sealing member, it comprises: first part, and it comprises following cross-linking products: the first cross-linked polymer; With the second cross-linked polymer; And second section, it comprises the polymkeric substance different from the formation polymkeric substance of first part, and wherein the second-order transition temperature of the seal has gradient.
In another embodiment, a kind of sealing method, it comprises: the seal is placed in opening; The seal is heated to the temperature of the minimum value of the second-order transition temperature being greater than sealing member; With apply pressure on the elastic part of the seal, to seal this opening.
Accompanying drawing explanation
Explanation below should not thought restrictive by any way.With reference to this accompanying drawing, identical element adopts identical Reference numeral:
Figure 1A, 1B and 1C show the cross section of composition, and said composition has the cross-linking products of cross-linked polymer, and its second-order transition temperature has gradient;
Fig. 2 A and 2B shows the skeleton view of the goods with discontinuous and continuous print second-order transition temperature gradient;
Fig. 3 shows second-order transition temperature relative to along the chart of linear position of goods with second-order transition temperature gradient;
Fig. 4 A shows the skeleton view of elastomeric seal, and the seal comprises the composition with second-order transition temperature gradient;
Fig. 4 B and 4C shows before and after applying force of compression respectively, the cross section of elastomeric seal;
Fig. 5 A and 5B shows the cross section of the elastomeric seal respectively as single component and multiple assembly;
Fig. 6 A and 6B shows respectively before and after expansion, the cross section of pack-off element; With
Fig. 7 A and 7B shows respectively before and after expansion, the cross section of sliding members.
Embodiment
At this with reference to accompanying drawing, the unrestriced mode by example, is described in detail to one or more embodiments of disclosed materials and methods.
Have been found that the elastic composition of the cross-linking products containing cross-linked polymer is that the goods containing this elastic composition provide second-order transition temperature gradient.This elastic composition can valuably for goods such as sealing member, for wide with adjustable second-order transition temperature (Tg).Rely on this characteristic, be greater than the temperature of second-order transition temperature minimum value of these goods, the part comprising the goods of this elastic composition can be in vitreous state, and another part is in elastic state.Goods described here, at high temperature or high pressure, demonstrate flexibility within the time extended.
Here this new High Temperature High Pressure elastic composition room temperature be rigidity with tough, but show as rubber-like material in the temperature higher than room temperature.This elastic composition has excellent elasticity, resistance to extrudability and overall construction intensity at high temperature or high pressure.In particularly advantageous at one, the goods (such as sealing member) of this elastic composition act as their support (backup) sealing member in some temperature and maintain their excellent properties, are also even like this when using continuously.Due to this self-supporting performance, this elastic composition can advantageously use as High Temperature High Pressure sealing member.
Usually the polymer Typical ground classifying as elastomerics (rubber-like material) has single glass transition temperature (Tg), and it has one and starts temperature and lower than the transformation narrow temperature range of room temperature had from vitreous state to elastic state.These elastomericss when applied at elevated temperature deliquescing and through time thermal destruction.When these elastomericss be exposed to corrosive fluid and in conjunction with high temperature or high pressure time, degraded accelerate, like this this elastomerics can at short notice (such as a couple of days or even several hours) destroy completely.Propose a kind of scheme improving high temperature chemical-resistant, carry out the carbon in elasticity of substitution body main chain, to provide organo-silicone rubber with non-carbon such as organosilicon.Propose another program, keep elastomeric carbon backbone chain, but with fluoro for hydrogen.
Materials and methods described here represents different schemes, and it is based on the recognition, and namely elastomerics is without the need to having lower than room temperature and the Tg carried out in narrow temperature range, and this Tg is also without the need to being single value.Alternatively, this new elastic composition disclosed herein provides such goods through design, its second-order transition temperature (Tg) has gradient, and the minimum value of this Tg is higher than room temperature, but lower than the minimum application temperature (MAT) of this elastic composition.In addition, the Tg of this elastic composition is adjustable with wide, is present in wide temperature range.In addition, the goods with this elastic composition can have multiple discrete second-order transition temperature.Therefore, elastomerics here lower than being more similar to engineering plastics (rigidity with firm) during MAT, but higher than being elastic during MAT.Therefore, those polymkeric substance in the elastomer material of traditional classification are not limited to for the alternatives of this new High Temperature High Pressure elastic composition.But any polymkeric substance can developed, evaluate or be used in higher than having favorable elasticity during MAT.
Potential material for the manufacture of this high temperature elastomer composition comprises amorphous and semi-crystalline thermoplastic polymer, and it can be molecule crosslinked.The molecular chain of amorphous thermoplastic polymers shows as " random coil (random coils) ".After cross-linking, this ball of string tends to response external force and is out of shape in proportion, and after external force is removed, this ball of string tends to the initial construction recovering them.On the contrary, crystallization or semi-crystalline polymer have such region, and here molecular chain is rule alignment each other.Be not limited to theory, it is believed that the crosslinked of semi-crystalline polymer also can provide restorer, it, by making this semi-crystalline polymer after the external force making this semi-crystalline polymer be out of shape is removed, returns to its initial construction or main body geometrical shape.The molecule crosslinked degree of thermoplastic polymer can adjust based on this High Temperature High Pressure elastic composition selected materials and intended applications.In one embodiment, degree of crosslinking is change in this elastic composition, to set up second-order transition temperature gradient and to provide best elasticity.If this degree of crosslinking reaches high-density, then can increase rigidity and/or the brittleness of this elastic composition.
Therefore, in one embodiment, provide a kind of composition, it comprises the cross-linking products of the combination of cross-linked polymer, has second-order transition temperature gradient to make the goods comprising said composition.In one non-limiting embodiment, the combination of this cross-linked polymer comprises multiple cross-linked polymer such as the first cross-linked polymer and the second cross-linked polymer.Exemplary cross-linked polymer comprises crosslinked polyarylene, crosslinked polyarylene sulfide, crosslinked polyaryl sulfone and crosslinked polysulfones.In a specific embodiment, this cross-linked polymer be crosslinked polyphenylene sulfide (x-PPS), crosslinked Polyphenylene Sulfone (x-PPSU), crosslinked self-enhancement polyphenylene (x-SRP), crosslinked polyethers sulfone (x-PESU) or comprise the combination of aforementioned at least one.Therefore, in one embodiment, this cross-linking products comprises such as x-PPS, x-PPSU, x-SRP, x-PESU or comprises being cross-linked between the combination of aforementioned at least one.The declarative description of x-PPS, x-PPSU and x-SRP and respective manufacture method at U.S. Patent application 13/179,230,13/229,923,13/246,250,13/303,688 and 13/343, in 264, its respective disclosure is incorporated herein by reference in this entirety.
The combination with the cross-linked polymer of different chemical or physicals may be used for manufacturing this cross-linking products, such as the cross-linked polymer of different molecular weight, different replacement form, different viscosity or the different degree of branching.In one embodiment, the first cross-linked polymer is different from the second cross-linked polymer.Alternatively, first and second cross-linked polymers have identical molecular backbone chain (namely basic Polyphenylene Sulfone (PPSU), polyphenylene sulfide (PPS), self-enhancement polyphenylene (SRP) or polyethersulfone (PESU) main chain), and it has different chemistry or physicals.In a specific embodiment, the first and second polymer phases with and there is different molecular weight, different replacement forms, different viscosity or the different degrees of branching.In a specific embodiment, said composition comprises the cross-linking products of crosslinked polyphenylene sulfide, crosslinked polyphenylene sulfone and crosslinked self-enhancement polyphenylene.
This cross-linked polymer can be obtained by heat cross-linking base polymer under oxygen, sulphur or its combination existence.This base polymer can be polyphenylene sulfide, Polyphenylene Sulfone, self-enhancement polyphenylene, polyethersulfone etc.Operable exemplary polyaryl sulfone comprises Polyphenylene Sulfone, and it is available from the source of such as Solvay Specialty Polymers, Quadrant EPP, Centroplast Centro, Duneon, GEHR Plastics, Westlake Plastics and Gharda Chemicals.The Polyphenylene Sulfone of commercial grades comprises trade mark and is called
with
those.An example of polyaryl sulfone comprises with trade name
be purchased from those of 3M.Exemplary polyphenylene sulfide comprises those with branched structure, such as by Chevron-Phillips with trade name
sell those, there are those of linear structure, such as by Ticona with trade name
sell those, or its combination.Operable exemplary self-enhancement polyphenylene comprises by Solvay Advanced Polymers with trade name
commercially available those of PR-250.Exemplary polyethersulfone comprises by ICI with trade name
commercially available those.
This cross-linked polymer can be prepared by the mode being similar to the cross-linking products producing following cross-linked polymer.In one embodiment, this cross-linked polymer is prepared by oxidative crosslinking base polymer under molecule crosslinked dose of existence.In one embodiment, this molecule crosslinked dose can be oxygen (pure oxygen or come from the mixture of the gas comprising oxygen, such as there is or do not have the air of rare gas element such as nitrogen, helium, argon gas, carbonic acid gas), inorganic oxidizer (such as magnesium oxide), organic oxidizing agent (such as dicumyl peroxide) etc.In one embodiment, crosslinkedly to carry out in atmosphere.Can the pressure (>1 normal atmosphere) of environment for use pressure or rising, or the dividing potential drop lower than environmental stress can be used.The crosslinked of base polymer can about 200 DEG C of-Yue 400 DEG C, in another embodiment about 250 DEG C of-Yue 390 DEG C, and the temperature of about 300 DEG C of-Yue 380 DEG C is in another embodiment carried out.Set time is less than or equal to 200 hours, is less than the total time of 75 hours specifically.Contrary with base polymer, this cross-linked polymer is insoluble to solvent such as METHYLPYRROLIDONE (NMP) or Ν, Ν-dimethyl formamide (DMF), and it may be used for confirming molecule crosslinked generation.This cross-linked polymer also demonstrates rubber-like platform (plateau) in the temperature higher than its Tg, and it has relatively high modulus.In one embodiment, the Tg of crosslinked polyphenylene is increased to 180 DEG C of crosslinked polyphenylene from 120 DEG C of base polymer (polyphenylene), this uses dynamic mechanical analysis (DMA) to measure, and it may be used for the Young's modulus and the storage modulus that measure cross-linked polymer.
The Tg of this cross-linked polymer is higher than envrionment temperature.In one embodiment, the Tg of this cross-linked polymer is more than or equal to about 50 DEG C, is more than or equal to about 100 DEG C specifically, and is more specifically more than or equal to about 150 DEG C, and is even more specifically more than or equal to about 200 DEG C.In another embodiment, the storage modulus of this cross-linked polymer is more than or equal to about 1 MPa (MPa), about 1.2MPa and more specifically about 1.5MPa specifically, this is in the temperature measuring being more than or equal to about 250 DEG C, be more than or equal to about 275 DEG C in another embodiment, and be more than or equal to about 300 DEG C in another embodiment.
The relative quantity of the cross-linked polymer merged can change.In one embodiment, the merging of cross-linked polymer comprises the first cross-linked polymer and the second cross-linked polymer, wherein the amount of the first cross-linked polymer can be about 5 weight percent (wt%)-Yue 95wt%, can be about 5 weight percent (wt%)-Yue 95wt% with the amount of the second cross-linked polymer, based on the weighing scale of the combination of cross-linked polymer.In another embodiment, the combination of this cross-linked polymer comprises first, second, and third cross-linked polymer, wherein the amount of first, second, and third cross-linked polymer can be about 0.01 (wt%)-Yue 95wt% separately, based on the weighing scale of this cross-linked polymer.In yet another embodiment, the combination of cross-linked polymer comprises multiple cross-linked polymers of any relative weight percents.In one embodiment, the goods of said composition have the concentration gradient of this cross-linked polymer any.In another embodiment, the goods with said composition have the concentration gradient of the first cross-linked polymer.In another embodiment, the goods with said composition have the gradient of the ratio of the amount of cross-linked polymer in the combination of cross-linked polymer.In a specific embodiment, the goods with said composition have the gradient of the amount of the first cross-linked polymer and the ratio of the amount of the second cross-linked polymer.In one embodiment, the amount of the first cross-linked polymer is 1:1000-1000:1 with the ratio of the amount of the second cross-linked polymer, 1:100-100:1 and more specifically 1:50-50:1 specifically, based on the weighing scale of the first and second cross-linked polymers.
According to an embodiment, said composition comprises additive.Crosslinked together and formed before its cross-linking products at them, this additive can merge with cross-linked polymer.As wide in range use here, additive comprises any compound, and it joins in this cross-linked polymer or cross-linking products, to regulate the performance of this elastic composition, and such as filler, linking agent or processing aid.
As used herein, filler comprises enhancement and non-enhanced filler.Enhancement filler comprises such as silicon-dioxide, glass fibre, carbon fiber or carbon black, and it can join in polymeric matrix to gain in strength.Non-enhanced filler is tetrafluoroethylene (PTFE), MoS2 or graphite such as, can add in this cross-linked polymer to increase oilness.Nano filling is also useful, and can be enhancement or non-reinforcing.Nano filling is carbon nanotube, nano-graphene, nanoclay, polyhedral oligomeric silsesquioxane (POSS) etc. such as, can mix with the intensity increasing said composition and elongation with this cross-linked polymer.Nano filling functionalizedly further can comprise grafting or functional group, with adjusting function such as solvability, surface charge, wetting ability, lipotropy and other performances.The combination comprising aforementioned at least one filler can be used.
The cross-linking products of this elastic composition, by under molecule crosslinked dose of existence, makes the combination oxidative crosslinking of cross-linked polymer prepare.Linking agent comprises oxygen and solid or liquid cross-linker such as superoxide, metal oxide or sulphur.
When oxygen is used as linking agent, this oxygen can provide with the gas of pure oxygen or gaseous mixture form.When using gaseous mixture, oxygen can with the merging such as rare gas element such as nitrogen, helium, argon gas.Other gases can exist, such as carbonic acid gas etc.In one embodiment, air is used.This crosslinked can at environmental stress, in the dividing potential drop lower than environmental stress or carry out at the pressure (being greater than 1 normal atmosphere) raised.
Superoxide may be used for being cross-linked, such as organo-peroxide such as ketone peroxide, diacyl peroxide, dialkyl peroxide, peroxyester, ketal peroxide, hydroperoxide, peroxy dicarbonate and peroxidation monocarbonate.The example of concrete superoxide comprises 2, two (tert-butyl hydroperoxide) butane, 1 of 2-, 4-two (t-butylperoxyisopropyl) benzene, dicumyl peroxide, tert-butyl cumyl peroxide, 2,5-dimethyl-2,5-bis--(tert-butyl peroxide) hexane, 4,4 '-two (tert-butyl hydroperoxide) n-butyl pentanoate, 1,1 '-two (tert-butyl hydroperoxide)-3,3,5-trimethyl-cyclohexane etc.; Or inorganic peroxide is calcium peroxide, zinc peroxide, hydrogen peroxide, peroxidisulfates etc. such as.Commercially available superoxide comprises by Arkema, Inc. with trade name
sell those, comprise
dialkyl peroxide,
40C dialkyl peroxide (on calcium carbonate carrier),
40K dialkyl peroxide,
40KE dialkyl peroxide; With alkyl diperoxy compound compound, comprise 2,5-dimethyl-2,5-bis-(tert-butyl hydroperoxide) hexane, and by Akzo-Nobel with trade name
101 sell.The superoxide of significant quantity easily can be determined according to the factor of the reactivity of such as superoxide and cross-linked polymer, required degree of cure and similar consideration by those skilled in the art, and can determine without the need to undo experimentation.Such as, the consumption of superoxide can be the cross-linked polymer of about 1-about 10 weight part/100 weight part.
The metal oxide that can be used as linking agent comprises such as zinc oxide, magnesium oxide, titanium dioxide etc. or its combination.According to an embodiment, crosslinked they with before forming cross-linking products, magnesium oxide and cross-linked polymer are merged.Sulphur also may be used for being cross-linked, such as elemental sulfur.The combination of aforementioned crosslinking agent can be used.
Known in the art also can exist for other reagent caused or accelerate to solidify, such as amine accelerator, sulphonamide accelerator etc.The linking agent, activator etc. of significant quantity are known in the art, and can determine without the need to undo experimentation.
As oxygen, crosslinked under superoxide, sulphur or other molecule crosslinked dose exist can at environmental stress, lower than the dividing potential drop of environmental stress or carry out at the pressure (being greater than 1 normal atmosphere) raised.When using superoxide, sulphur or another solid or liquid cross-linker, this reagent is usual and cross-linked polymer is compounding, and then it be optionally shaped and be cross-linked.This linking agent can pre-dispersedly join in cross-linked polymer to masterbatch neutralization to promote mixing.
Processing aid is compound, and it is involved improves the mobility of the elastic composition containing this cross-linking products, moldability and other performances.Processing aid comprises such as oligopolymer, wax, resin, fluorocarbon etc. or comprises the combination of aforementioned at least one.Exemplary processing aid comprises stearic acid and derivative, low molecular weight polyethylene etc.
This cross-linked polymer can be cross-linked separately or be cross-linked under another kind of polymkeric substance exists, to obtain the desired properties of the cross-linking products of this elastic composition.But the existence of other polymkeric substance can reduce chemical-resistant.Therefore, in one embodiment, during forming cross-linking products, there are not other polymkeric substance crosslinked.If used, then in order to keep the desired properties of the elastic composition containing this cross-linking products, the other polymkeric substance of any amount is shown, such as, exists with the amount of 0.01-20wt%, 0.1-10wt% or 1-5wt% of existing cross-linked polymer gross weight.Such as, in use, aromatic thermoplastic polymer can be there is, such as aromatic poly amide, polyimide, polyetherimide, polyphenylene sulfide (PPS), PAEK (PAEK), polyether-ether-ketone (PEEK), polyethersulfone (PESU), PPSU (PPSU), PPSU urea etc., or comprise the composition of aforementioned at least one.Oxygen containing polymkeric substance can be used, comprise such as Derlin (such as polyoxymethylene (POM)), vibrin (such as poly-(ethylene terephthalate) (PET), poly-(terephthalic acid Aden ester) (PBT) and poly-(naphthalic acid ethyl) (PEN)), polyacrylic ester (PAR), poly-(phenylene ether) (PPE), polycarbonate (PC), aliphatic polyketones (such as polyketone (PK)), poly-(ether ketone) (polyetherketone (PEK), PEKK (PEKK) and polyetherketoneetherketoneketone (PEKEKK)) and acrylic resin (such as polymethylmethacrylate (PMMA)).This other polymkeric substance can be linear or the homopolymer of branching or multipolymer, and is used alone or combinationally uses with one or more other aromatic thermoplastic polymer.Multipolymer comprise random, alternately, grafting and segmented copolymer, the segmented copolymer with two or more different homopolymer blocks, random copolymers or alternating copolymer.This thermoplastic polymer chemical modification can comprise such as functional group as groups such as halogen, alcohol, ether, ester, acid amides further, or can be oxidized, hydrogenation etc.Reactive elastomerics or fluoropolymer crosslinked with blended with cross-linked polymer before forming cross-linked polymer, and can be grafted to the flexibility of the cross-linking products this cross-linked polymer increasing this elastic composition in crosslinked period.The example of reactive elastomerics or fluoropolymer comprise tetrafluoroethylene (PTFE), butyronitrile-isoprene-isobutylene rubber (NBR), hydrogenated butyronitrile-isoprene-isobutylene rubber (HNBR), high Oil repellent fluoroelastomer rubber such as sell in FKM race and with following trade name those:
fluoroelastomer (can available from FKM-Industries) and Perfluoroelastomer such as FFKM (also can available from FKM-Industries) and with trade name
the Perfluoroelastomer (can available from DuPont) sold, and
binding agent (can available from Dexco LP), the polydimethylsiloxane (PDMS) that organopolysiloxane is such as functionalized or unfunctionalized, tetrafluoroethylene-propylene elastomer copolymer is such as with trade name
sell and sold by Asahi Glass Co. those, Ethylene-Propylene-Diene monomer (EPDM) rubber, polyvinyl alcohol (PVA) etc., and comprise the composition of at least one aforementioned polymer.
According to an embodiment, this elastic composition comprising the cross-linking products of cross-linked polymer is prepared by making above-mentioned base polymer oxidative crosslinking manufacture cross-linked polymer.Compounding or molded before this cross-linked polymer is pulverized.Pulverizing can be undertaken by any suitable method, comprises and uses mortar and pestle, ball mill, mill etc., as long as the granularity of the cross-linked polymer of the pulverizing formed is suitable for fully mixing.Any suitable granularity can obtain by pulverizing.In one embodiment, this cross-linked polymer is crushed to granularity and is less than or equal to about 10 orders, be less than or equal to about 20 orders in another embodiment, and be less than or equal to about 40 orders in another embodiment.Will be appreciated that " being less than " order number size refers to the granularity defined by order number, itself and granularity negative correlation, namely order number is higher, and granularity is less.According to an embodiment, this cross-linked polymer is pulverized the powder, pellet or the particle that obtain cross-linked polymer.
Being combined through manually or merging two or more cross-linked polymers in device such as mixing tank, blender, forcing machine, mould etc. of cross-linked polymer is produced.In one embodiment, this cross-linked polymer uses variable feeding rate to be incorporated in device or container.Therefore, the feeding rate of each cross-linked polymer can be same to each other or different to each other.In addition, each feeding rate can independent of any other feeding rate.Because the feeding rate of each cross-linked polymer can change, therefore this cross-linked polymer can simultaneously, different time be incorporated in this device, and to open and close with different rate modulation with in the selected time.
In a specific embodiment, cross-linked polymer is incorporated in forcing machine.Optionally, additive is also placed in forcing machine together with cross-linked polymer.First cross-linked polymer introduces forcing machine with the first feeding rate, and the second cross-linked polymer is introduced with the second feeding rate.In one embodiment, the first and second cross-linked polymers are introduced simultaneously, are in the same position of extruder barrel to make two kinds of cross-linked polymers.According to an embodiment, the feeding rate changing cross-linked polymer obtains the concentration gradient of cross-linked polymer relative quantity.In one embodiment, cross-linked polymer can be fed forcing machine, then another cross-linked polymer can be fed this forcing machine, obtain thereafter the concentration gradient of cross-linked polymer in an extruder.The feeding rate of the first cross-linked polymer can reduce, and increases the feeding rate of the second cross-linked polymer simultaneously.When cross-linked polymer is advanced through forcing machine, they are heated, compress and crosslinked to form cross-linking products.This cross-linking products is passed through two die head to manufacture multi-form elastic composition, such as sheet, pipe, ring, pellet, conduit etc.Goods prepared by the elastic composition produced thus have second-order transition temperature gradient.In addition, contain in the goods of elastic composition at such, degree of crosslinking can change.
According to another embodiment, this cross-linked polymer is arranged in mould, such as compression mould.Be similar to forcing machine, cross-linked polymer can simultaneously, different time or introduce with the different timed intervals.Additive can optionally be placed together with cross-linked polymer.Therefore, the different positions in mould can have one or more cross-linked polymers of different amount, to produce the concentration gradient of cross-linked polymer relative quantity.In load after this cross-linked polymer, this cross-linked polymer can compress and heat the cross-linking products to form cross-linked polymer.In this way, degree of crosslinking can change in the goods with elastic composition.The goods with elastic composition produced thus have transition temperature gradient.Can carry out the temperature of 150 DEG C-350 DEG C 200 hours by this cross-linked polymer crosslinked to form cross-linking products or less, be less than 100 hours specifically to realize.
Figure 1A, 1B and 1C show the cross section of composition, and it has the cross-linking products of cross-linked polymer, and have second-order transition temperature gradient.In figure ia, elastic composition 20 comprises first cross-linked polymer 10 (being shown as dashed curve) and the combined cross-linking products with the second cross-linked polymer 14 (solid-line curve) of the second crosslinked 16 (stains) with the first crosslinked 12 (white points).First cross-linked polymer 10 is linked to crosslinked 18 (the grey points) of the second cross-linked polymer 14 by product.Here, product crosslinked 18 non-uniform Distribution in elastic composition 20, to set up second-order transition temperature gradient in containing the goods of elastic composition.Therefore, the goods with elastic composition 20 have central section 22, and it has the minimum value starting between the vitreous state of elastic composition 20 and elastic state to change.In addition, the second-order transition temperature gradient with the goods of elastic composition 20 is uniform.
See Figure 1B, the goods with elastic composition 24 comprise the concentration gradient of the first cross-linked polymer and the second cross-linked polymer, and in central section 22, have the peak concentration that product is cross-linked 18.Although Figure 1A and 1B illustrates to have the most high-density that product is cross-linked 18 in central section 22, the method that can control to be formed elastic composition selects the specific region of the elastic composition of the cross-linking products with maximum degree of crosslinking.In one embodiment, as shown in Figure 1 C, the goods with elastic composition 26 have discontinuous second-order transition temperature gradient.First cross-linked polymer 10 have shared relative little overlap with the second cross-linked polymer 14, to make these goods with elastic composition have second-order transition temperature gradient, be characterised in that along elastic composition 26 length direction D1 more than a kind of second-order transition temperature.In another embodiment, these goods with elastic composition can have continuous print and discontinuous both second-order transition temperature gradients.
Due to second-order transition temperature gradient, the article exhibits with elastic composition goes out the beginning changed between vitreous state and elastic state, and it changes according to the concrete part of goods elastomer composition.In one embodiment, these goods with elastic composition have the first part being in vitreous state and the second section being in elastic state, and it is exposed to the temperature of the minimum value of the second-order transition temperature being greater than this elastic composition according to the goods that this has elastic composition.In a specific embodiment, elastic state is present in and is more than or equal to 200 °F, is more than or equal to 400 °F particularly, is more specifically more than or equal to 600 °F, and is even more specifically more than or equal to the temperature of 700 °F.In another embodiment, elastic state is present in 200 °F of temperature to the heat decomposition temperature of elastic composition.The heat decomposition temperature of this elastic composition is more than or equal to 500 °F, is more than or equal to 600 °F particularly, is more specifically more than or equal to 700 °F, and is even more specifically more than or equal to 800 °F.
These goods with elastic composition have glass transition (transformation namely between elastic state and vitreous state), it is at least Fahrenheitscale 50 degree, 100 degree specifically, 150 degree more specifically, 200 degree even more specifically, the temperature field of still 250 degree and still Fahrenheitscale 375 degree even more specifically more specifically carries out.Therefore, in one non-limiting embodiment, the glass transition between the elastic state of elastic composition and vitreous state carries out on the temperature field of 200 degree (Fahrenheitscales).Here, the goods having elastic composition in response to this are heated by from such as room temperature (at this moment this elastic composition is in vitreous state), this part with the goods of elastic composition will be elastic state from glassy transition at the minimum value place of second-order transition temperature, with make this part such as 300 °F time become rubber-like.Because glass transition occurs on the temperature field of 200 degree in this embodiment, therefore this different piece with the goods of elastic composition will be elastic state from glassy transition at height to 500 °F.It should be noted that these goods with elastic composition can have wide diffusing glass transition temperature (carrying out on certain temperature field) here, instead of for the narrow temperature window of Tg.Therefore, according to an embodiment, these goods with elastic composition at 180 °F-550 °F, more specifically 200 °F-500 °F, even more specifically 200 °F-400 °F and still more specifically the temperature field of 300 °F-500 °F has second-order transition temperature gradient.Consider that glass transition gradient covers these temperature, these goods with elastic composition it is said to have such as 180 °F-550 °F, more specifically 200 °F-500 °F, even more specifically 200 °F-400 °F and the still more specifically second-order transition temperature of 300 °F-500 °F.In addition, there is the minimum value of the second-order transition temperature of the goods of elastic composition corresponding to minimum temperature during these goods formation rubber-like part.Such as, if second-order transition temperature gradient is 180 °F-550 °F, then the minimum value of second-order transition temperature will be 180 °F.
Relevant with this second-order transition temperature is storage modulus.The storage modulus of this elastic composition is 4MPa-16MPa, and 8MPa-12MPa specifically, and it is 302 °F of mensuration.This elastic composition is also erosion resistance liquids and gases, and has long storage life and long continuous work-ing life, exceedes the several years under elevated temperature and pressure conditions.
The goods comprising this elastic composition are prepared in many ways.In one embodiment, the method preparing goods comprises merging first cross-linked polymer and the second cross-linked polymer to form composition.First cross-linked polymer is linked on the second cross-linked polymer, to form described goods by said composition compression (such as in forcing machine or mould) and heating.Linking agent can be introduced together with the second cross-linked polymer with the first cross-linked polymer, and the first and second cross-linked polymers can be powder, pellet, fiber or the combination comprising aforementioned at least one.In one embodiment, the first cross-linked polymer and the second cross-linked polymer can be introduced with the first feeding rate and the second feeding rate respectively.In addition, the first and second feeding rates can be changes.In another embodiment, the feeding rate of the first cross-linked polymer can reduce, and the feeding rate of the second cross-linked polymer can increase simultaneously.This cross-linked polymer can merge in mould, forcing machine, mixing tank, blender etc.In a specific embodiment, this cross-linked polymer experienced by compression and heating in stamping method.In another embodiment, the amount of the first cross-linked polymer can change during the first and second cross-linked polymers merge with the ratio of the amount of the second cross-linked polymer.
The goods manufactured thus have the performance of this elastic composition.In one embodiment, the goods comprising this elastic composition have second-order transition temperature gradient, and it is continuous print, discontinuous or its combination.In another embodiment, these goods have crosslink density gradient.In another embodiment, these goods have the gradient of the relative quantity of cross-linked polymer.
These goods are more than or equal to 10,000 pounds/square inch (ksi) the compressive strength of 500 °F, are more than or equal to 20ksi specifically, and are more than or equal to 32ksi more specifically.
The goods here with second-order transition temperature gradient can be formed with many different shapes, the such as shape etc. of ring, pipe, conduit, rod, annular, spheroid, Polygons, taper, cylinder, its truncation.Such shape can be formed by method of moulding, extrude etc.In addition, this molded shape can experience different manufacturing process further, comprises cutting, saw solution, ablation (ablating) and other materials removing method.
These goods may be used for widely in multiple environment, and can be used for any can use in the application of elastomeric seal.Because these goods have wide elastomer temperature scope (such as 200 °F-700 °F) here, also be even like this at high pressure, these goods can carry out being used as sealing element in the device, fixture, instrument etc. of elastomeric seal and such as hold cup (swab cup), labyrinth (chevron seal), O shape ring, T-shaped ring, packing ring, pkr etc. any.In one embodiment, the sealing member during these goods are used as in down-hole application mud motor.In another embodiment, these goods are used as the sealing member in the load lock chamber of semiconductor test vacuum chamber.
Therefore, in one embodiment, sealing member comprises elastic composition here.According to another embodiment, these goods such as sealing member can be placed in opening, is heated to the temperature of the minimum value of the second-order transition temperature being greater than the seal, and can exerts pressure on the elastic part of the seal, seal described opening.In another embodiment, the seal can be cooled to certain temperature, comprises the first part being in vitreous state and the second section being in elastic state to make the seal.
Other polymkeric substance can be used for forming a sealing member part, are namely different from one or more other polymkeric substance of the polymkeric substance in the part with Tg gradient.Other polymkeric substance used in sealing member can be thermoset or thermoplastic, and comprise elastomerics particularly.The example of other polymkeric substance comprises epoxide, ethylene propylene diene rubber (EPR), ethylene propylene diene monomer rubber (EPDM), trimeric cyanamide, polyacetal, polyacrylamide, polyacrylic is polyacrylic acid such as, polyacrylonitrile, polymeric amide comprises polyamidoimide, poly (arylene ether), poly (arylene sulfide), polyarylene sulfone, polybenzoxazole, polybenzothiozole, polyhutadiene and multipolymer thereof, polycarbonate-based, polycarbonate, polyetherketone, polyether-ether-ketone, PEKK, polyethersulfone, polyester, polyimide is polyetherimide such as, polyisoprene and multipolymer thereof, polyolefines is as polyethylene and multipolymer thereof, polypropylene and multipolymer thereof, and tetrafluoroethylene, polyphosphonitrile, poly-(alkyl) (methyl) acrylate, polystyrene and multipolymer thereof, the polystyrene such as acrylonitrile-butadiene-styrene (ABS) (ABS) of modified rubber, styrene ethylene butadiene (SEB) and MBS (MBS), polyoxadiazole, polysilazane, polysulfones, polysulphonamide, polyvinyl acetate, polyvinyl chloride, polyvinylesters, polyvingl ether, polyvinylhalide, polyvinyl nitrile, polyvinyl thioethers, polyureas, urethane and organosilicon.The combination comprising at least one aforementioned polymer can be used.In one embodiment, these other polymkeric substance are polybenzimidazole.Should be understood that, " difference " represents that this polymkeric substance at least one performance is different, such as degree of crosslinking or crosslink type.Therefore, but the crosslinked polyphenylene sulfide that polymkeric substance such as has the first degree of crosslinking or a Tg is different from and has identical main chain degree of crosslinking or the different polymkeric substance of Tg.
As previously mentioned, these goods can have continuous print or discontinuous second-order transition temperature gradient.Fig. 2 A shows the skeleton view of the goods 30 with discontinuous second-order transition temperature.End 32,34 has large cross-linking density, and centre portions 36 has relatively low cross-linking density.Therefore, the second-order transition temperature of centre portions 36 is lower than the second-order transition temperature corresponding to end 32,34.As a result, when goods 30 heat from the temperature (temperature of centre portions 36) of minimum value of the second-order transition temperature being less than it, centre portions 36 becomes elastic prior to end 32,34.If temperature to be remained on the second-order transition temperature lower than end 32,34, then they will remain glassy, and will compress and twisting center part 36 along the power that goods 30 longitudinally apply, and such distortion has been resisted in end 32,34.Will be appreciated that such design allows goods 30 to show as its supporting sealing member.That is, because end 32,34 can be in vitreous state, and centre portions 36 is in elastic state, then centre portions 36 is by end 32,34 " support ", and goods 30 do not need outside supporting sealing member or element.Supporting sealing member uses together with conventional elastomers (such as fluoroelastomer) with ring, this is owing to this conventional elastomers extruding under compressibility power, comprise along the malleation of this conventional elastomers and negative pressure (relative to a normal atmosphere) the two.
Should be understood that, here this elastic composition and goods can thermal cyclings repeatedly between low temperature (such as freezing temp) and high temperature (such as slightly lower than the temperature of cross-linking products decomposition temperature), and this elastic composition and goods will keep their chemistry, physical and mechanical property, and depart from significantly without it.In addition, even such as be greater than 3 months at low temperature or high temperature immersion longer time, be greater than 6 months particularly, after being more specifically greater than 1 year and being still more specifically greater than 2 years, this elastic composition and goods still will keep their chemistry, physical and mechanical property, and depart from significantly without it.
In addition, these goods can be heated to above the maximum value of second-order transition temperature, to obtain these goods elasticity completely or almost completely.Subsequently, these goods can be cooled to the temperature between the maximum value of the second-order transition temperature of these goods and minimum value, to make these goods comprise to be in the part of vitreous state and to be in the part of elastic state, and this temperature can be carried out immersion these goods are remained on portions glassy-partial elastic state.By being further cooled to the minimum value of the second-order transition temperature lower than these goods, these goods turn back to vitreous state completely or almost completely.In addition, this thermal cycling can repeat, and does not damage described goods, or can repeat any part of this thermal cycling, to regulate this goods between completely glassy, perfect elasticity or portions glassy-partial elastic state.
Fig. 2 B shows the skeleton view of goods 40, and these goods have continuous second-order transition temperature gradient, and it represents with the change tone of gray level 42.The region 44 of most high crosslink density has the most black value of gray level, and the region 46 of minimum cross-linking density represents by the most shallow value of gray level.Equally, the region with minimum cross-linking density corresponds to the minimum value of the second-order transition temperature of goods 40.For the goods 40 with continuous print second-order transition temperature gradient, be glass region from elastic region to the minimum value higher than second-order transition temperature will be level and smooth transformation.
These goods can be formed with different shapes, and the selectivity can with the low of cross-linking products or high crosslink density arranges district.During minimum value higher than the second-order transition temperature of these goods, applying power can make the elastic part of these goods be out of shape.Such distortion allows these goods to form different shape of cross sections, and it can be used in the use application of certain limit, such as, pkr in subsurface environment or sliding part.
Fig. 3 shows the goods 50,52,54,56 for having initial cylindrical, and second-order transition temperature (Tg) is relative to the figure of the position (x) along a dimension.The bottom of each goods 50,52,54,56 is starting position x0, and the top of each goods 50,52,54,56 is final position x2 (x-axis for this figure).The skeleton view of the goods 50,52,54,56 of initial cylindrical appears at the tight right side of this figure, and the cross-linking density had represented by the gray scale level shown in each goods, wherein the most black gray scale level (black) illustrates maximum degree of crosslinking, and the minimum gray scale level (white) of minimum degree of crosslinking represents.From second-order transition temperature minimum value (Tg_min) to the temperature being less than second-order transition temperature maximum value (Tg_max), the force of compression be applied between the top (x1) of goods (50,52,54,56) and bottom (x2) creates the shape of cross section of the goods (50,52,54,56) shown in the rightmost side of Fig. 3.Each goods (50,52,54,56) this temperature-resistant shape, and maintain its initial cross sectional sum shape corresponding to the part of the second-order transition temperature maximum value of these goods.Each goods (50,52,54,56) corresponding to the part of the second-order transition temperature minimum value of these goods in this temperature deformation, to increase its cross-sectional area.In this way, the goods containing elastic composition (it has the cross-linking products of cross-linked polymer) can have the shape of adjustment, and it is activated by temperature or pressure.In another embodiment, replace force of compression, this power is the tension force applied at the top of goods and bottom, to make the part of these goods (it is in the temperature of the second-order transition temperature higher than them) be out of shape by stretching, and there is the cross-sectional area of the power shape that in advance the apply reduction initial compared to them.In still another embodiment, power is applied to this goods with the angle certain relative to the longitudinal axis of these goods.This angle can be 0 °-180 ° relative to the longitudinal axis.Under this power, these goods can be deformed into different shape of cross sections in the temperature of the second-order transition temperature minimum value being greater than these goods.
In another embodiment, these goods can be the O shape ring of elastomeric seal such as shown in Fig. 4 A, 4B and 4C.O shape ring 60 has external diameter 66, internal diameter 68 and second-order transition temperature gradient, has high Tg part 62 and low Tg part 64.O shape ring 60 is placed in sealed tube 70, make this O shape annular strain with temperature (corresponding to the low Tg part 64) power be applied on O shape ring 60 in the second-order transition temperature minimum value higher than O shape ring 60, with make it be filled with a sealing pipe 70 and between external diameter 66 and internal diameter 68 formed sealing.In one embodiment, this temperature is between second-order transition temperature maximum value and minimum value and (corresponds respectively to high Tg part 62 and low Tg part 64), and high Tg part 62 is in vitreous state and serves the supporting role of low Tg part 64 (it is in elastic state).Although O shape ring 60 is represented as have discontinuous second-order transition temperature gradient, O shape ring can have continuous print or discontinuous second-order transition temperature gradient here.
In another embodiment, these goods can be the elastomeric seal such as labyrinths shown in Fig. 5 A and 5B.Labyrinth 80 has external diameter 82, internal diameter 84 and second-order transition temperature gradient, it is provided by the part of the labyrinth 80 with different degree of crosslinking (being represented by gray scale level in fig. 5), and the highest and minimum cross-linking density represents with black and white gray scale level respectively here.It should be noted that the position in labyrinth (and other goods here), the combination of length (i.e. degree) and different degree of crosslinking can be formed by selecting elastic composition in required processing conditions (feeding rate of such as cross-linked polymer and crosslinking temperature) change.Although Fig. 5 A labyrinth 80, Fig. 5 B shown as monolithic shows the cross section of labyrinth 86, it comprises the discrete sheet 88 be in stacking construction.Each sheet 88 can have second-order transition temperature gradient, or sheet 88 can be pure cross-linked polymer, and it is not linked to another kind of cross-linked polymer.The shape of labyrinth 80 can be formed as the cross section of Fig. 5 A.In one embodiment, the shape of labyrinth 80 can make labyrinth 80 be in the portion deforms of elastic state (this is owing to the temperature of labyrinth) by making firmly (such as waterpower) and be formed.
In another embodiment, these goods are the pkrs for down-hole in drilling well, as shown in Figure 6 A and 6B.Pkr 90 has external diameter 92, internal diameter 94 and second-order transition temperature gradient, and its low Tg part 96 by pkr 90 and high Tg part 98 provide.The internal diameter 94 of pkr 90 surrounds the pipe 100 of wall or the casing inner diameter being positioned at drilling well 102.When the temperature of pkr 90 reaches the value between the minimum value of the second-order transition temperature of pkr 90 and maximum value, force of compression can apply along pkr 90, and the external diameter 92 corresponding to low Tg part 96 expands towards borehole wall 102.Pkr 92 launches when its external diameter 92 contacts borehole wall 102, seals the annular space between pipe 100 and borehole wall 102.Second-order transition temperature gradient can be continuous print or discontinuous, and this can by the shape that affect pkr 92 that expands.Down-hole is heated this pkr 92 and can be carried out by any method, and it heated the region around pkr 92.Exemplary type of heating comprises hot-fluid injection, steam injection, heat-producing chemical reaction etc.
According to another embodiment, these goods be can down-hole use sliding part, such as there is stopper such as bridge or pressure break plug.Fig. 7 A and 7B shows the cross section of the sliding part 110 on the end being positioned at pressure break plug 112.Sliding part 110 has external diameter 114, internal diameter 116 and second-order transition temperature gradient, and its low Tg part 118 by sliding part 110 and high Tg part 120 provide.Sliding part 110 and pressure break plug 112 are positioned at the internal diameter of borehole wall 122.When the temperature of sliding part 110 reaches the value between the minimum of the second-order transition temperature of sliding part 110 and maximum value, force of compression can be applied to this sliding part 110, and the external diameter 114 corresponding to low Tg part 118 expands towards borehole wall 122.Sliding part 110 launches when its external diameter 114 contacts borehole wall 122, this prevent pressure break plug 112 position superior displacement from it in borehole wall 122.This second-order transition temperature gradient can be continuous print or discontinuous, and this can by the shape of expansion effects sliding part 110.Heating sliding part 110 down-hole, down-hole can be carried out by any method, and it heated the region around sliding part 110, is similar to heating pkr 92.
Although shown and described one or more embodiments, can change it and replace, and not depart from the spirit and scope of the invention.Therefore, be to be understood that the present invention is described by way of illustration, not of limitation.Here embodiment independently can use or can merge.
Four corner disclosed herein includes end points, and this end points can combine independently of one another.As used herein, suffix " (s) " object is both the odd number and plural number that comprise the term that it is modified, comprises this term of at least one (such as, tinting material (s) comprises at least one tinting material) thus." optional " or " optionally " represents that event described subsequently or situation can occur or can not occur, and this description includes the situation that this event occurs and the situation that this event does not occur.As used herein, " composition " comprises blend, mixture, alloy, reaction product etc.Whole reference is hereby incorporated by.
In description context of the present invention (in the context specifically at appended claims), term " one " and " one " and " being somebody's turn to do " and similar referring to is used to be interpreted as covering both odd number and plural number, unless otherwise directed or contradiction obvious with context.As used herein, term " " comprises at least one element that " " is prefix, and such as " device " comprises " at least one device "." or " represent "and/or".In addition, should it is further noted that here term " first ", " second " etc. do not represent any order, amount (be greater than as existed a kind of, two kinds or more than the element of two kinds) or importance, but for element is distinguished from each other.The correction word " about " used that is connected with amount includes described value, and has the implication (such as it comprises the error degree relevant with the measurement of Specific amounts) described in context.
Claims (29)
1. goods, it comprises:
Following cross-linking products:
First cross-linked polymer; With
Second cross-linked polymer,
The second-order transition temperature of these goods has gradient.
2. goods according to claim 1, wherein the first cross-linked polymer comprises crosslinked polyphenylene sulfide, crosslinked Polyphenylene Sulfone, crosslinked self-enhancement polyphenylene, crosslinked polyethers sulfone or comprises the combination of aforementioned at least one.
3. goods according to claim 2, wherein the second cross-linked polymer comprises crosslinked polyphenylene sulfide, crosslinked Polyphenylene Sulfone, crosslinked self-enhancement polyphenylene, crosslinked polyethers sulfone or comprises the combination of aforementioned at least one.
4. goods according to claim 1, wherein these goods comprise the cross-linking products of crosslinked polyphenylene sulfide, crosslinked Polyphenylene Sulfone and crosslinked self-enhancement polyphenylene.
5. goods according to claim 1, it comprises additive further, and this additive comprises silicon-dioxide, glass fibre, carbon fiber or carbon black or comprises the combination of aforementioned at least one.
6. goods according to claim 1, the concentration of the wherein combination of the first cross-linked polymer of these goods, the second cross-linked polymer or at least aforementioned at least one has gradient.
7. goods according to claim 1, wherein the amount of the first cross-linked polymer of these goods has gradient with the ratio of the amount of the second cross-linked polymer.
8. the goods of claim 7, wherein the amount of the first cross-linked polymer is 1:1000-1000:1 with the ratio of the amount of the second cross-linked polymer, based on the weighing scale of the first and second cross-linked polymers.
9. goods according to claim 1, wherein these goods have the first part corresponding to the first second-order transition temperature, and correspond to the second section of the second second-order transition temperature, in this gradient, first second-order transition temperature is greater than the second second-order transition temperature, and
Wherein be exposed to the minimum value of the second-order transition temperature being greater than these goods according to these goods and be less than the temperature of the maximum value of the second-order transition temperature of these goods, first part is in vitreous state, and second section is in elastic state.
10. goods according to claim 1, wherein this elastic state is 200 °F-700 °F existence.
11. goods according to claim 1, wherein these goods have the glass transition carried out on the temperature field of Fahrenheitscale 300 degree.
12. goods according to claim 1, wherein these goods have and are being greater than the glass transition that the temperature field of Fahrenheitscale 100 degree carries out.
13. goods according to claim 1, this gradient wherein in glass transition corresponds to the temperature field of 200 °F-500 °F.
14. goods according to claim 1, this gradient wherein in second-order transition temperature is continuous print.
15. goods according to claim 1, this gradient wherein in second-order transition temperature is discontinuous.
16. goods according to claim 1, wherein the first cross-linked polymer has the first cross-linking density, and the second cross-linked polymer has the second cross-linking density.
17. goods according to claim 16, wherein the first cross-linking density is different from the second cross-linking density.
18. goods according to claim 1, wherein the first cross-linked polymer is different from the second cross-linked polymer.
19. goods according to claim 1, wherein the heat decomposition temperature of these goods is greater than 700 °F.
20. 1 kinds of goods, it comprises:
Following cross-linking products:
First cross-linked polymer; With
Second cross-linked polymer,
Wherein the second-order transition temperature of these goods has gradient, and cross-linking density has gradient, and these goods are configured to have self-supporting performance in the minimum Tg value of second-order transition temperature gradient to the temperature being less than maximum Tg value.
21. 1 kinds of methods manufacturing goods, the method comprises:
Merge the first cross-linked polymer and the second cross-linked polymer to form composition;
Compression said composition;
Heating said composition; With
Crosslinked said composition is to form this goods, and the second-order transition temperature of these goods has gradient.
22. methods according to claim 21, it comprises further introduces linking agent in the first cross-linked polymer, the second cross-linked polymer or its combination.
23. methods according to claim 21, wherein said merging comprises:
First cross-linked polymer is introduced with the first feeding rate; With
Second cross-linked polymer is introduced with the second feeding rate,
Wherein both the first feeding rate, the second feeding rate or the first and second feeding rates are variable.
24. methods according to claim 23, wherein merge and comprise:
Reduce the first feeding rate of the first cross-linked polymer; With
Increase the second feeding rate of the second cross-linked polymer.
25. methods according to claim 23, during it is included in merging first and second cross-linked polymer further, change the ratio of the amount of the first cross-linked polymer and the amount of the second cross-linked polymer.
26. 1 kinds of sealing members, it comprises:
First part, it comprises following cross-linking products:
First cross-linked polymer; With
Second cross-linked polymer; And
Second section, it comprises the polymkeric substance different from the formation polymkeric substance of first part,
Wherein the second-order transition temperature of the seal has gradient.
27. sealing members according to claim 26, the polymkeric substance wherein in second section is heat cured, thermoplastic or comprises the combination of aforementioned at least one.
28. 1 kinds of sealing methods, it comprises:
Sealing member according to claim 27 is placed in opening;
The seal is heated to the temperature of the second-order transition temperature minimum value being greater than this gradient; With
Apply pressure to the elastic part of the seal, to seal this opening.
29. methods according to claim 28, it comprises further adjusts to certain value by the temperature of the seal, this value is less than the first second-order transition temperature corresponding to the seal first part being in vitreous state, and this value is greater than the second second-order transition temperature corresponding to the seal second section being in elastic state, wherein in this gradient, the first second-order transition temperature is greater than the second second-order transition temperature.
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DK2852633T3 (en) | 2019-12-09 |
WO2013176792A1 (en) | 2013-11-28 |
BR112014028231A2 (en) | 2017-06-27 |
CN104321369B (en) | 2018-03-13 |
CA2873725A1 (en) | 2013-11-28 |
AU2013266885B2 (en) | 2016-08-11 |
MY168423A (en) | 2018-11-09 |
BR112014028231B1 (en) | 2020-10-13 |
CA2956602A1 (en) | 2013-11-28 |
CA2956602C (en) | 2018-05-15 |
EP2852633A4 (en) | 2016-01-13 |
AU2013266885A1 (en) | 2014-11-20 |
US8952105B2 (en) | 2015-02-10 |
US20130313780A1 (en) | 2013-11-28 |
CA2873725C (en) | 2017-03-21 |
EP2852633A1 (en) | 2015-04-01 |
US9453577B2 (en) | 2016-09-27 |
EP2852633B1 (en) | 2019-09-25 |
US20150069711A1 (en) | 2015-03-12 |
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